Network system to filter requests by destination and deadline

ABSTRACT

A method and system for filtering service requests by destination and deadline are described. A network computer system receives provider data corresponding to a specified destination and a deadline from a service provider. The network computer system tracks a current location of the service provider through a device equipped with one or more location-based resources and receives request data corresponding to requests for service from users. The network computer system analyzes the request data for each of the requests for service to identify a subset of the requests that are assignable to the service provider based on whether the service provider is able to fulfill the request and travel to the desired destination before the deadline. The network computer system transmits a message to the service provider&#39;s device requesting that the service provider fulfill one of the requests for service from the identified subset.

CROSS REFERENCE TO RELATED APPLICATION

This application is a Continuation of U.S. patent application Ser. No.15/432,766, entitled “NETWORK SYSTEM TO FILTER REQUESTS BY DESTINATIONAND DEADLINE,” filed on Feb. 14, 2017; which application is herebyincorporated by reference in its entirety.

BACKGROUND

A network service can enable users to request and receive variousservices through applications on mobile computing devices. The networkservice typically selects a service provider to fulfill the request forservice based on user-specified data from the request. These serviceproviders can interact with the network service to accept or declineservice requests, receive data about the requesting users, and setvarious status modes such as whether the provider is online andavailable to fulfill requests or offline.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram illustrating an example network computersystem in communication with service requester and service providerdevices, in accordance with examples described herein.

FIG. 2 is a timeline illustrating examples of events that can occurwhile providing services in a deadline filter mode, in accordance withexamples described herein.

FIG. 3 is a flow chart describing an example method of filtering servicerequests by destination and deadline, according to examples describedherein.

FIG. 4 is a flow chart describing an example method of persistingdestination and deadline settings when a service provider goes offline,according to examples described herein.

FIG. 5 is a flow chart describing an example method of filtering servicerequests by destination, according to examples described herein.

FIGS. 6A and 6B illustrate example user interfaces on a service providerdevice, according to examples described herein.

FIG. 7 is a block diagram illustrating an example service providerdevice executing a designated service provider application for anon-demand service, as described herein.

FIG. 8 is a block diagram that illustrates a computer system upon whichaspects described herein may be implemented.

DETAILED DESCRIPTION

A network computer system is provided herein that manages an on-demandnetwork-based service linking available service providers with servicerequesters throughout a given region (e.g., a metroplex such as the SanFrancisco Bay Area). According to examples, the network computer systemcan receive service requests for on-demand services (e.g., transportservice or delivery service) from requesting users (e.g., a rider) via adesignated service requester application executing on the users' mobilecomputing devices. Based, at least in part, on a service start location,the network computer system can identify a number of proximate availableservice providers (e.g., a driver) and transmit a service invitationmessage to one or more service provider devices of the proximateavailable service providers to fulfill the service request (e.g.,provide or perform the corresponding service). In many examples, theservice providers can either accept or decline the invitation based on,for example, the service start location or service destination beingimpractical for the service provider.

In some examples, in selecting a service provider to fulfill a givenservice request, the network computer system can identify a plurality ofcandidate service providers to fulfill the service request based on aservice start location indicated in the service request. For example,the network computer system can determine a geo-fence (e.g., a regionspecified by three or more location points or a defined area, such as ahexagon from an array of hexagons) surrounding the service startlocation (or a geo-fence defined by a radius away from the service startlocation), identify a set of candidate service providers (e.g., twentyor thirty service providers within the geo-fence), and select an optimalservice provider (e.g., closest service provider to the service startlocation, service provider with the shortest estimated travel time fromthe service start location, service provider traveling to a locationwithin a specified distance or specified travel time to the destinationlocation, etc.) from the candidate service providers to fulfill theservice request. According to examples provided herein, the networkcomputer system can compile historical data for individual servicerequesters with regard to the network-based service. Thus, the networkcomputer system can manage a service requester profile for each servicerequester indicating routine start and/or end locations (or regions),and/or routine routes (e.g., for a transportation service from home towork and/or vice versa) and preferred service types (e.g.,transportation, delivery, mailing, etc.). In some examples, the networkcomputer system can further synchronize with a service requester deviceto, for example, identify the service requester's contacts, the servicerequester's schedule and appointments, travel plans (e.g., a scheduledtrip), and the like.

In conventional service requester applications used with on-demandservice systems, service providers may be reluctant to go online or stayonline when they have limited time because of fears that trips couldlead them far away from a desired destination, such as home or work. Ifthe provider needs to be at a specified destination by a given deadline,they may choose to play it safe and not risk providing services at all.

In various implementations described herein, the service provider isable to specify at what time they want to arrive at a specificdestination. With those data, an example network computer system canoperate to filter service requests to obey a set of constraints thatallow a service provider to be at a desired or specified destination bya deadline time. Additionally or alternatively, in one example, when thenetwork computer system receives a service request, the network computersystem can determine whether to include the service provider (whospecified a desired destination and deadline) in the set of candidateservice providers to fulfill the service request based on the dataprovided. The network computer system can then select a service providerfrom this set. Thus, the network computer system can ensure that theservice provider is not chosen to receive service invitations or beassigned to services that would take that service provider too far awayfrom the desired destination such that he or she could not arrive thereprior to the requested deadline. In addition, the network computersystem ensures that not only can the service provider arrive at thedesired destination prior to the deadline, but also that the providerhas sufficient time to provide services to requesting users near theestimated route from the provider's current location to the desireddestination. Moreover, once the network computer system determines thatit is time for the service provider to head towards the destination, itconfirms with the service provider that he or she still wants to be atthe specified destination by the deadline. Once confirmed, the networkcomputer system filters out any service requests in which the servicestart location and the service destination are not roughly along a routeof travel from the provider's current location to the desireddestination. That is, the network computer system can filter out theservice provider from a candidate pool of drivers for any invitationsfor services that are not in a similar direction as the route of travel.In some aspects, the network computer system 100 can determine that arequest for service is along a route of travel when the request has aservice start location and/or service destination that are within athreshold distance from a point along the route of travel.

Among other benefits, the examples described herein achieve a technicaleffect of providing on-demand network-based service providers (e.g., anon-demand transportation service) with increased control and stabilityover scheduling. By programmatically filtering service requests bydestination and deadline, the network computer system prevents serviceproviders from providing services that would otherwise have led them toofar away to make it to their desired destinations at specified deadlinetimes. This gives service providers more peace of mind and flexibilitywhen providing services through the network computer system, which canincrease the average usage of the system and reduce waiting times forusers.

According to examples described herein, a network computer systemreceives provider data corresponding to a desired destination and adeadline from a service provider. The network computer system tracks acurrent location of the service provider through a device equipped withone or more location-based resources and receives request datacorresponding to requests for service from users. The network computersystem analyzes the request data for each of the requests for service toidentify a subset of the requests in which the service provider isdetermined to be able to fulfill the request and travel to the desireddestination before the deadline. In other words, the network computersystem can identify, from the plurality of requests, one or morerequests that are assignable to the service provider based on adetermination that the service provider is capable of providing serviceand traveling to the specified destination before the deadline. Thenetwork computer system transmits an invitation to the service providerto fulfill one of the requests for service from the identified subset.

As provided herein, the terms “user” and “service requester” are usedthroughout this application interchangeably to describe a person orgroup of people who utilize a requester application on a computingdevice to request, over one or more networks, on-demand services from anetwork computing system. The term “service provider” is used todescribe a person utilizing a provider application on a computing deviceto provide on-demand services to the service requesters.

One or more aspects described herein provide that methods, techniquesand actions performed by a computing device are performedprogrammatically, or as a computer-implemented method. Programmaticallymeans through the use of code, or computer-executable instructions. Aprogrammatically performed step may or may not be automatic.

One or more aspects described herein may be implemented usingprogrammatic modules or components. A programmatic module or componentmay include a program, a subroutine, a portion of a program, a softwarecomponent, or a hardware component capable of performing one or morestated tasks or functions. In addition, a module or component can existon a hardware component independently of other modules or components.Alternatively, a module or component can be a shared element or processof other modules, programs or machines.

Furthermore, one or more aspects described herein may be implementedthrough the use of instructions that are executable by one or moreprocessors. These instructions may be carried on a computer-readablemedium. Machines shown or described with figures below provide examplesof processing resources and computer-readable media on whichinstructions for implementing some aspects can be carried and/orexecuted. In particular, the numerous machines shown in some examplesinclude processor(s) and various forms of memory for holding data andinstructions. Examples of computer-readable media include permanentmemory storage devices, such as hard drives on personal computers orservers. Other examples of computer storage media include portablestorage units, such as CD or DVD units, flash or solid state memory(such as carried on many cell phones and consumer electronic devices)and magnetic memory. Computers, terminals, network enabled devices(e.g., mobile devices such as cell phones) are all examples of machinesand devices that utilize processors, memory, and instructions stored oncomputer-readable media.

Alternatively, one or more examples described herein may be implementedthrough the use of dedicated hardware logic circuits that are comprisedof an interconnection of logic gates. Such circuits are typicallydesigned using a hardware description language (HDL), such as Verilogand VHDL. These languages contain instructions that ultimately definethe layout of the circuit. However, once the circuit is fabricated,there are no instructions. All the processing is performed byinterconnected gates.

System Overview

FIG. 1 is a block diagram illustrating an example network computersystem in communication with service requester and service providerdevices, in accordance with examples described herein. The networkcomputer system 100 can implement or manage a network service (e.g., anon-demand transport or delivery arrangement service) that connectsservice requesters 174 with service providers 184 that are available tofulfill the service requests 171 that service requesters 174 transmit tothe network computer system 100. The network service can enable servicesto be requested by service requesters 174 and provided by availableservice providers 184 by way of a service requester application 175executing on the service requester devices 170, and a service providerapplication 185 executing on the service provider devices 180. As usedherein, a service requester device 170 and a service provider device 180can comprise computing devices with functionality to execute designatedapplications corresponding to the on-demand arrangement service managedby the network computer system 100. In many examples, service requesterdevices 170 and service provider devices 180 can comprise mobilecomputing devices, such as smartphones, tablet computers, virtualreality or augmented reality headsets, on-board computing systems ofvehicles, and the like. Example network services can comprise deliveryof food or products, package mailing, shopping, construction, plumbing,home repair, housing or apartment sharing, etc., or can includetransportation arrangement services.

The network computer system 100 can include a provider managementinterface 115 to communicate over one or more networks 160 with theservice provider application 185 running on service provider devices180. According to examples, service providers 184 register with thenetwork computer system 100 to receive service invitations 132 throughthe service provider application 185 to fulfill service requests 171submitted by the service requesters 174. In an example using transportservices, the service requesters 174 are prospective passengers who wantto be picked up and transported, and the service providers 184 aredrivers who transport the service requesters 174.

Service providers 184 can select various states or modes within theservice provider application 185, such as an online mode that indicatesthe service provider 184 is available and willing to fulfill serviceinvitations 132. Service providers 184 can also select from varioustypes of transport service that the provider offers, includingride-pooling, a basic ride-share service type, a luxury vehicle servicetype, etc. In addition, service providers 184 can set one or moreconstraints on their schedule, such as a desired destination 114 and/ordeadline 116.

In some situations, service providers 184 make themselves available toperform services for a block of time in a manner similar to a work shiftor at sporadic times whenever convenient for the provider. For example,a driver providing transport services may choose to only pick uppassengers during a morning commute or on the way home in the evening.In the normal course of providing on-demand services, the serviceproviders 184 can either park and wait or drive around a region waitingfor nearby users to request services. However, service providers 184 maybe reluctant to go online or stay online when they have limited timebecause of fears that trips could lead them far away from a desireddestination such as home or work. Therefore, the network computer system100 can operate to filter service requests 171 to obey a set ofconstraints that allow a service provider 184 to be at a desireddestination 114 by a deadline 116.

In accordance with various examples, the service provider device 180transmits a provider status 113, which can include any selected modes,the current location of the service provider 184, and other providerinformation, over the network 160 to the provider management interface115. In addition, the service provider device 180 can transmit a desireddestination 114 and deadline 116 to the provider management interface115 when the service provider 184 chooses to enter a filtering mode. Insome implementations, the service provider devices 180 can determine thecurrent location of the service provider 184 using location-basedresources of the service provider devices 180 (e.g., global positioningsystem (GPS) resources). The service provider application 185 cancontinually update the provider status 113 on a regular schedule or inresponse to provider input to the service provider device 180, locationchanges determined by GPS, service steps performed, etc. The providermanagement interface 115 stores the provider status 113 in a providerdata store 190 (e.g., a database or data structure) accessible by aselection engine 130 that processes incoming service requests 171 inorder to select service providers 184 to fulfill the service requests171.

The network computer system 100 can include a service requesterinterface 125 to communicate with service requester devices 170 over oneor more networks 160 via a service requester application 175. Accordingto examples, a service requester 174 wishing to utilize the on-demandarrangement service can launch the service requester application 175 andtransmit a service request 171 over the network 160 to the networkcomputer system 100. In certain implementations, the service requester174 can view multiple different service types managed by the networkcomputer system 100, such as ride-pooling, a basic ride-share servicetype, a luxury vehicle service type, a van or large vehicle servicetype, professional services (e.g., where the service provider iscertified), an on-demand self-driving vehicle service, and the like. Thenetwork computer system 100 can utilize service provider locations toprovide the service requester devices 170 with estimated time to arrival(ETA) data of proximate service providers 184 for each respectiveservice. In one implementation, the service requester application 175can enable the service requester 174 to scroll through each servicetype. In response to a soft selection of a particular service type, thenetwork computer system 100 can provide ETA data on a user interface ofthe service requester application 175 that indicates an ETA of theclosest service provider 184 for the service type and/or the locationsof all proximate available service providers 184 for that service type.As the service requester 174 scrolls through each service type, the userinterface can update to show visual representations of the serviceproviders 184 for that service type on a map centered on the servicerequester 174 or a chosen service start location 173. The servicerequester 174 can interact with the user interface of the servicerequester application 175 to select a particular service type andtransmit a service request 171.

In some examples, the service request 171 can include a service startlocation 173 within a given region (e.g., a metropolitan area managed byone or more datacenters corresponding to the network computer system100) where a matched service provider is to rendezvous with the servicerequester 174. The service requester 174 can input the service startlocation 173 by setting a location pin on a user interface of theservice requester application 175, or the service start location 173 canbe determined by a current location of the service requester 174 (e.g.,utilizing location-based resources of the service requester device 170).Additionally, the service requester 174 can input a service destination172 during or after submitting the service request 171. In an exampleusing transport services, the service requester 174 is a prospectivepassenger that wants to be picked up at the service start location 173and dropped off at the service destination 172.

The network computer system 100 can include a mapping engine 135, or canutilize a third-party mapping service, to generate map data 137 and ortraffic data in the environment surrounding the service start location173. The mapping engine 135 can retrieve service provider locations 118from the provider data store 190 and input them onto the map data 137.The selection engine 130 can utilize the provider locations 118 in orderto select an optimal service provider 189 to fulfill the service request171. As provided herein, the optimal service provider 189 can be aprovider that is closest to the service requester 174 with respect todistance or time, or can be a proximate provider that is optimal forother reasons, such as the provider's experience, the amount of time theprovider has been on the clock, the provider's current earnings, and thelike.

In some aspects, the selection engine 130 can implement filters,including destination filter 138 and deadline filter 139, to ensure thatservice providers 184 are not chosen to receive service invitations 132that would take them too far away from a desired destination 114 suchthat they could not arrive there prior to a deadline 116. Using theservice provider application 185, service providers 184 can input adeadline 116 specifying what time they would like to stop providingservice and a destination 114 specifying where they would like to be atthat time. The service provider device 180 can send provider datacorresponding to the desired destination 114 and deadline 116 to theprovider management interface 115. For example, a driver providingtransport services could select that he or she wants to be home at 7p.m. In this example, the destination is the provider's home address andthe deadline is 7 p.m. In one alternative implementation, the providermanagement interface 115 can programmatically determine the destination114 and deadline 116 for use cases such as hourly rentals.

The provider management interface 115 can process the destination 114and deadline 116 request and update a mode assigned to the serviceprovider 184 to reflect the new settings. In some aspects, the providermanagement interface 115 can verify the destination 114 and anyconstraints on the minimum and maximum acceptable deadlines 116 toconfirm the validity of the request. The provider management interface115 can also determine whether the service provider 184 meets anynecessary conditions to activate the deadline filter mode. For example,features of the deadline filter mode, such as the ability to specify adestination, may be limited in frequency of use. Once verified, theprovider management interface 115 can place the service provider 184 inthe deadline filter mode. In this mode, the selection engine 130attempts to ensure that the service provider 184 does not receiveservice invitations 132 that would take the provider too far away fromthe destination 114 such that he or she would be unable to reach thedesired destination 114 by the deadline 116. The provider managementinterface can also save the provider data in the provider data store 190and retain these data even when the service provider 184 goes offlinefor breaks or other reasons.

In order to ensure that the service provider 184 can reach the desireddestination 114 by the deadline 116, the network computer system 100tracks the current location of the service provider 184, and theselection engine 130 estimates how long it should take the serviceprovider 184 to reach the destination 114 while providing services torequesting users along the way. At periodic intervals while the serviceprovider 184 is in deadline filter mode, such as every time the currentlocation of the service provider 184 changes or once per minute, theselection engine 130 adds the estimate to the current time and comparesthat to the deadline 116 to determine whether the deadline threshold hasbeen reached.

The estimate of how long it should take the service provider 184 toreach the destination 114 includes estimates for the time it would taketo get to the destination 114 if the service provider 184 went theredirectly from the current location plus any time spent providingservices to requesting users along the way. In one aspect, the selectionengine 130 can implement a destination filter mode that offers serviceproviders 184 only the service requests 171 that the provider canfulfill along the way to the specified destination 114. In an examplewhere the service provider 184 is a driver offering transport services,the time spent providing services can account for expected delays thatarise through taking a detour to pick riders up and drop them off aswell as expected wait times for riders to get in and out of the car.This time can be expressed as theexpected_time_to_arrival_with_destination_filter. One example estimatefor that time is:direct_time_to_destination_from_current_location*1.5+20 minutes

The direct_time_to_destination_from_current_location is estimated frommapping resources, such as the mapping engine 135, and the constants areconfigurable. The multiplier accounts for the fact that a longerdistance tends to yield more intermittent service requests 171. Theoffset ensures enough buffer time when the destination 114 is nearby. Inother aspects, historical data of trip times 195 from a historical datastore 194 that are collected from service providers 184 in thedestination filter mode are used to estimate theexpected_time_to_arrival_with_destination_filter.

As soon as the calculated duration is equal to or greater than the timeleft until the deadline 116 the provider set, the provider managementinterface 115 informs the service provider 184 that it is time to headto the destination 114 through a mode change request 117 promptdisplayed on the service provider device 180. If the service provider184 is currently providing service to a user when the providermanagement interface 115 determines that it is time to head towards thedestination 114, the service provider application 185 can wait until theservice is completed and then inform the service provider 184 that he orshe should head to the destination 114.

In response to the prompt to head to the destination 114, the serviceprovider 184 can choose to enter destination filter mode, set a newdeadline 116, or remove the deadline 116 entirely. The providermanagement interface 115 can then process the service provider 184response to the prompt. If the service provider 184 chooses to enterdestination filter mode (e.g., by providing input), the providermanagement interface 115 sets the provider mode and expects the providerto travel towards the destination 114. From then on, the selectionengine 130 offers the service provider 184 only service invitations 132that are on the route from the current location to the destination 114.Therefore, in destination filter mode, the invites offered to theservice provider 184 should not take the service provider 184 too faraway from the route such that he or she cannot make it to thedestination 114 prior to the deadline 116. In some aspects, the serviceprovider 184 can configure destination filter mode settings so thatservice invitations 132 can cause the deadline 116 to be exceeded by afudge factor (e.g., 5 minutes). Additionally, in some examples, while indestination filter mode, the service provider 184 can receivepreferential treatment (i.e., boosting) from the network computer system100 and is considered higher priority than providers in normal mode forservice invitations 132 that are along the route.

Prior to the deadline threshold being reached, the selection engine 130offers the service provider 184 service invitations 132 without anyrestrictions on direction. However, the offered service invitations 132are constrained by a deadline filter 139 that checks whether the serviceprovider 184 has time to fulfill the service invitation 132 and stillreach the destination 114 while providing services to requesting usersalong the way. Therefore, when the requester interface 125 receives aservice request 171 from a user, the selection engine 130 estimates thetime required for the service provider 184 to travel from the currentlocation to the service start location, the service start location tothe service destination, and the service destination to the desireddestination 114.

In order to determine whether a received service request 171 passes thedeadline filter 139, the selection engine 130 can calculate an expectedtime for the service provider 184 to complete the service request 171.In one example, the expected time at completion is the current time plusan estimate for the time to travel from the current location to theservice start location and then from the service start location to theservice destination, taking into account factors such as trafficconditions and time required at each location to perform aspects of theservice. The deadline filter 139 can additionally estimate how long itshould take the service provider 184 to travel from the servicedestination to the desired destination 114 while still accepting andfulfilling service requests 171 along the way to the desired destination114, expressed as the expected_time_to_arrival_with_destination_filter.One example estimate for that time is:direct_time_to_destination_from_service_destination*1.5+20 minutes

As with the deadline threshold, the deadline filter calculation canestimate direct_time_to_destination_from_service_destination frommapping resources, such as the mapping engine 135 and trip times 195from a historical data store 194. In some implementations, the constantscan be configured to more accurately estimate times if data show thatthe default constants are suboptimal. The multiplier accounts for thefact that a longer distance tends to yield more intermittent servicerequests 171. The offset ensures enough buffer time when the destination114 is nearby. In other aspects, historical data collected from serviceproviders 184 in the destination filter mode are used to estimate theexpected_time_to_arrival_with_destination_filter. As a result, thedeadline filter 139 more aggressively filters out service requests 171as the deadline 116 approaches and/or the service provider 184 travelsfurther from the desired destination 114.

The deadline filter 139 then adds the expected time at completion andthe expected_time_to_arrival_with_destination_filter and compares theresult to the deadline 116. If the result is on or before the deadline116, the request passes the destination filter and the service provider184 is a possible candidate for fulfilling the service request 171. Ifthe result is after the deadline 116, the network computer system 100filters out the service provider 184 from a candidate set of providersand instead chooses a different provider from the candidate set tofulfill the service request 171. In alternative implementations, theselection engine 130 can instead choose an optimal service provider 189from the candidate set of providers prior to checking whether therequest passes any filters. In this case, if the chosen optimal serviceprovider 189 is in deadline filter mode, the selection engine 130 thenchecks whether the request passes the deadline filter 139, and if not,chooses the next available service provider 184.

Once the optimal service provider 189 is selected, the selection engine130 can generate a service invitation 132 to fulfill the service request171 and transmit the service invitation 132 to the optimal serviceprovider's device via the service provider application 185. In additionto the service invitation 132, the network computer system 100 cantransmit requester information 147, such as a name and photograph of theservice requester 174, from a requester data store 192. Upon receivingthe service invitation 132, the optimal service provider 189 can eitheraccept or reject the invitation 132. Rejection of the invitation 132 cancause the selection engine 130 to determine another optimal serviceprovider 189 from the candidate set of service providers 184 to fulfillthe service request 171. However, if the optimal service provider 189accepts (e.g., via an acceptance input), then the acceptance input istransmitted back to the selection engine 130, which generates andtransmits a confirmation of the optimal service provider 189 to theservice requester 174 via the service requester application 175 on theservice requester device 170.

In some aspects, the provider management interface 115 can continuemonitoring the deadline threshold while the service provider 184 isfulfilling a service request 171. If the service provider 184 iscurrently providing service to a user when the provider managementinterface 115 determines that it is time to head towards the destination114, the service provider application 185 can wait until the service iscompleted and then inform the service provider 184 that he or she shouldhead to the destination 114. Since the request for the current servicebeing performed passed the deadline filter 139, this can happen only insituations where traffic conditions on the route worsen significantly orother aspects of the service request 171 take significantly longer thanestimated.

Prior to reaching the destination 114, the destination filter 138 on theselection engine 130 filters out service requests 171 so that theprovider is only offered service invitations 132 that are along theroute from the provider's current location to the destination 114.Therefore, when the network computer system 100 receives a servicerequest 171 from a user, the network computer system 100 checks theservice start location and service destination and determines whetherpaths from the provider's current location to the service start locationand service destination are near or along the route from the currentlocation to the desired destination 114. If they are not, the selectionengine 130 filters out the service provider 184.

According to examples provided herein, the network computer system 100can include a content engine 120 that manages the manner in whichcontent is displayed on the service requester devices 170 and/or theservice provider devices 180. Regarding the service requester devices170, the content engine 120 can provide content updates based on userinputs 179 on a user interface generated by the service providerapplication 185. For example, a user selection on a content feature ofthe service provider application 185 can cause the content engine 120 togenerate a new screen on the service provider application 185 or cause acurrent screen to pivot between certain displayed features. Wheninputting a particular destination 114, the service provider 184 mayutilize a location pin and map content and set the location pin on aparticular location in the map content to input the destination 114.Additionally, the content engine 120 can adjust the look and feel of adeadline input box to overlay the map content, which can enable theservice provider 184 to select a time for the deadline 116.

In various implementations, the requester data store 192 can storeservice requester profiles specific to the individual users of theon-demand service. Such information can include user preferences ofservice types, routine routes, service start locations 173 and servicedestinations 172, work addresses, home addresses, addresses offrequently visited locations (e.g., a gym, grocery store, mall, localairport, sports arena or stadium, concert venue, local parks, and thelike). In addition, the provider data store 190 can store serviceprovider profiles indicating information specific to individualproviders, such as vehicle type, service qualifications, earnings data,and provider experience. Database 140 can also store historical data 141regarding service requester and service provider liquidity for a givenarea, that is, how often a new service provider 184 is expected to makethemselves available for on-demand services in the area.

FIG. 2 is a timeline illustrating examples of events that can occurwhile providing services in a deadline filter mode, in accordance withexamples described herein. At the start of the timeline, the networkcomputer system 100 can receive a destination and a deadline from aservice provider that specify what time the service provider would liketo stop providing service and where that service provider would like tobe at that time. For example, a driver could select that he or she wantsto be home at 7 p.m. In this example, the destination is the provider'shome address and the deadline is 7 p.m.

At starting time 201, a provider management interface 115 of the networkcomputer system 100 can process the destination and deadline request andupdate the mode assigned to the service provider to reflect the receiveddestination and deadline. In some aspects, the provider managementinterface 115 can verify the destination and any constraints on theminimum and maximum acceptable deadlines to confirm the validity of therequest. The provider management interface 115 can also determinewhether the service provider meets any necessary conditions to activatethe deadline filter mode. For example, features of the deadline filtermode, such as the ability to specify a destination, may be limited infrequency of use. Once verified, the provider management interface 115can place the service provider in the deadline filter mode. In thismode, the network computer system 100 attempts to ensure that theservice provider does not receive service invitations that would takethe provider too far away from the destination such that he or she wouldbe unable to reach the desired destination by the deadline.

Prior to the deadline threshold being reached, the network computersystem 100 offers the service provider service invitations without anyrestrictions on direction. However, the offered service invitations areconstrained by a deadline filter that checks whether the serviceprovider has time to fulfill the service invitation and still reach thedestination while providing services to requesting users along the way(i.e., traveling to the destination in destination filter mode). Forexample, when the network computer system 100 receives a service requestfrom a user, the network computer system 100 estimates the time requiredfor the service provider to travel from the current location to theservice start location, the service start location to the servicedestination, and the service destination to the desired destination. Inan example using transport services, the user is a prospective passengerthat wants to be picked up at the service start location and dropped offat the service destination.

In order to determine whether a received service request passes thedeadline filter, the network computer system 100 can calculate anexpected time for the service provider to complete the service request.In one example, the expected time at completion is the current time plusan estimate for the time to travel from the current location to theservice start location and then from the service start location to theservice destination, taking into account factors such as trafficconditions and time required at each location to perform aspects of theservice. The deadline filter can additionally estimate how long itshould take the service provider to travel from the service destinationto the desired destination while still accepting and fulfilling servicerequests along the way to the desired destination, expressed as theexpected_time_to_arrival_with_destination_filter. One example estimatefor that time is:direct_time_to_destination_from_service_destination*1.5+20 minutes

The deadline filter calculation can estimatedirect_time_to_destination_from_service_destination from mappingresources, such as the mapping engine 135, and the constants areconfigurable. The multiplier accounts for the fact that a longerdistance tends to yield more intermittent service requests. The offsetensures enough buffer time when the destination is nearby. In otheraspects, historical data collected from service providers in thedestination filter mode are used to estimate theexpected_time_to_arrival_with_destination_filter.

The deadline filter then adds the expected time at the servicedestination and the expected_time_to_arrival_with_destination_filter andcompares the result to the deadline. If the result is on or before thedeadline, the request passes the destination filter and the serviceprovider is a possible candidate for fulfilling the service request. Ifthe result is after the deadline, the network computer system 100filters out the service provider from a candidate set of providers andinstead chooses a different provider from the candidate set to fulfillthe service request. In alternative implementations, the networkcomputer system 100 can instead choose an optimal service provider fromthe candidate set of providers prior to checking whether the requestpasses any filters. In this case, if the chosen optimal service provideris in deadline filter mode, the network computer system 100 then checkswhether the request passes the deadline filter, and if not, chooses thenext available service provider.

In order to ensure that the service provider can reach the desireddestination by the deadline, the network computer system 100 tracks thecurrent location of the service provider and estimates how long itshould take the service provider to reach the destination whileproviding services to requesting users along the way (i.e., traveling tothe destination in destination filter mode). At periodic intervals whilethe service provider is in deadline filter mode, such as every time thecurrent location of the service provider changes or once per minute, thenetwork computer system 100 adds the estimate to the current time andcompares that to the deadline to determine whether the deadlinethreshold has been reached.

Once the deadline threshold is reached at inflection point 210, thenetwork computer system 100 informs the service provider that it is timeto head to the destination through a prompt displayed on the serviceprovider device 180. If the service provider is currently providingservice to a user when the network computer system 100 determines thatit is time to head towards the destination, the service providerapplication 185 can wait until the service is completed and then informthe service provider that he or she should head to the destination.

In response to the prompt to head to the destination, the serviceprovider can choose to enter destination filter mode, set a newdeadline, or remove the deadline entirely (e.g., by providing input).The network computer system 100 can then process the service providerresponse to the prompt. If the service provider chooses to enterdestination filter mode, the network computer system 100 sets theservice provider mode and expects the provider to travel towards thedestination. From then on, the network computer system 100 offers theservice provider only service invitations that are along the route fromthe current location to the destination. Therefore, in destinationfilter mode, the invites offered to the service provider should not takethe service provider too far away from the route such that he or shecannot make it to the destination prior to the deadline 216. In someaspects, the service provider can configure destination filter modesettings so that service invitations can cause the deadline to beexceeded by a fudge factor (e.g., 5 minutes). Additionally, while indestination filter mode, the service provider can receive preferentialtreatment (i.e., boosting) from the network computer system 100 and isconsidered higher priority than providers in normal mode for serviceinvitations that are along the route.

When the service provider is available to receive a new serviceinvitation (either through rejecting an invitation or completingservice), the network computer system 100 or the service provider device180 itself can monitor the service provider location to determine if theprovider has arrived at the desired destination. Once the provider hasarrived at the desired destination, the service provider application 185can place the service provider in an offline mode wherein the provideris not available to receive service invitations.

In one example use case, a service provider named Joe leaves his houseat 10 a.m. to provide transport services to local passengers. As heleaves the house in the morning, he sets his desired destination to hishome address in Palo Alto, Calif. and specifies an arrival deadline of 6p.m. His provider status is updated to the online state (e.g., availableto provide service) and he soon receives and accepts a serviceinvitation 132 to transport a passenger to San Jose. While he isproviding service, the provider status is in the busy or “on-trip”state.

At 11 a.m. in San Jose, Joe receives and accepts a service invitationwith a drop off location in San Francisco. At 1 p.m. in San Francisco,Joe goes offline using the service provider application 185 and takes aone-hour lunch break. While on break, the network computer system 100can retain Joe's destination and deadline settings so that they persistwhen he comes back online. At 2 p.m. in San Francisco, Joe comes onlineand receives a service invitation 132 sending him to Oakland, where hereceives multiple local service invitations 132 and drives around theOakland area.

At 4 p.m. in Oakland, a user near Joe requests a ride to San Jose.However, the network computer system 100 estimates that it would takeJoe 1.5 hours to pick up the user and drive to San Jose in currenttraffic conditions. The network computer system 100 further estimatesthat Joe could not get from San Jose at 5:30 p.m. to his home in PaloAlto by the 6 p.m. deadline. Therefore, the network computer system 100filters out Joe and chooses a different driver to take the user to SanJose. Instead, Joe receives a service invitation 132 back to SanFrancisco that meets the deadline threshold.

At 4:30 p.m. in San Francisco, another user near Joe requests a ride toSouth San Francisco. The network computer system 100 estimates that Joewould arrive by 5:15 p.m., and that the direct time from South SanFrancisco to Palo Alto is 40 minutes. Therefore, Joe's expectedestimated time to arrival (ETA) would be 5:55 p.m. However, using theexample destination filtering formula, the network computer system 100estimates that it would take 80 minutes (1.5*40 minutes+20 minutes) forJoe to drive from South San Francisco to Palo Alto while fulfillingservice requests along the route in destination filter mode. So despitebeing able to fulfill the service request to South San Francisco andreach his desired destination by the deadline, Joe would not have timeto fulfill further service requests while driving from South SanFrancisco to Palo Alto. As a result, the network computer system 100filters out Joe and chooses a different driver to take the user to SouthSan Francisco.

Instead, Joe receives a request from a user who wants a ride to MenloPark with an ETA at 5:25 p.m. The network computer system 100 estimatesthe time from Menlo Park to Joe's home as 6 minutes. Therefore, Joe'sexpected_time_to_arrival_with_destination_filter is 1.5*6 minutes+20minutes, which is 29 minutes. As it is currently 5:25 p.m., Joe'sexpected arrival time at home while in destination filter mode is 5:54p.m. This is before Joe's 6 p.m. deadline so he receives the serviceinvitation, which he accepts.

Joe drops off the rider in Menlo Park at 5:25 p.m. The network computersystem 100 determines that Joe should begin heading to his destinationin order to reach it before the 6:00 p.m. deadline. A prompt appears onhis device telling Joe that it is time to head home. After Joe confirms,the network computer system 100 switches Joe into destination filtermode to ensure he only receives service invitations that are near oralong the route from his current location in Menlo Park to his desireddestination in Palo Alto. That is, the network computer system 100filters out Joe from a candidate pool of drivers for any invitations forservices that are not in a similar direction as his route of travel. Insome aspects, the network computer system 100 can determine that arequest for service is along a route of travel when the request has aservice start location and/or service destination that are within athreshold distance from a point along the route of travel.

At 5:28 p.m. in Menlo Park, Joe receives one final service invitation topick up a nearby user and drop her off at an address roughly on the wayand 8 minutes from Joe's house in Palo Alto. He receives the invitationbecause the network computer system 100 estimates he can make it to thedrop off location by 5:50 p.m. At 5:50 p.m., Joe drops off the rider anddrives home, where he arrives and goes offline at 5:58 p.m.

Methodology

FIGS. 3 through 5 are flow charts describing example methods used infiltering service requests by destination and deadline. While operationsof the methods are described below as being performed by specificcomponents of the network computer system 100, it will be appreciatedthat these operations need not necessarily be performed by the specificcomponents identified, and could be performed by a variety of componentsand modules, potentially distributed over a number of machines.Accordingly, references may be made to elements of the network computersystem 100 for the purpose of illustrating suitable components orelements for performing a step or sub step being described.Alternatively, at least certain ones of the variety of components andmodules described in the network computer system 100 can be arrangedwithin a single hardware, software, or firmware component. It will alsobe appreciated that some of the steps of these methods may be performedin parallel or in a different order than illustrated.

FIG. 3 is a flow chart describing an example method of filtering servicerequests by destination and deadline, according to examples describedherein. The network computer system 100 can receive a destination and adeadline from a service provider that specify what time the serviceprovider would like to stop providing service and where that serviceprovider would like to be at that time (310). For example, a drivercould select that he or she wants to be home at 7 p.m. In this example,the destination is the provider's home address and the deadline is 7p.m.

A provider management interface 115 of the network computer system 100can process the destination and deadline request and update the modeassigned to the service provider to reflect the received destination anddeadline. In some aspects, the provider management interface 115 canverify the destination and any constraints on the minimum and maximumacceptable deadlines to confirm the validity of the request. Theprovider management interface 115 can also determine whether the serviceprovider meets any necessary conditions to activate the deadline filtermode. For example, features of the deadline filter mode, such as theability to specify a destination, may be limited in frequency of use.Once verified, the provider management interface 115 can place theservice provider in the deadline filter mode (312). In this mode, thenetwork computer system 100 attempts to ensure that the service providerdoes not receive service invitations that would take the provider toofar away from the destination such that he or she would be unable toreach the desired destination by the deadline.

In order to ensure that the service provider can reach the desireddestination by the deadline, the network computer system 100 tracks thecurrent location of the service provider and estimates how long itshould take the service provider to reach the destination whileproviding services to requesting users along the way. At periodicintervals while the service provider is in deadline filter mode, such asevery time the current location of the service provider changes or onceper minute, the network computer system 100 adds the estimate to thecurrent time and compares that to the deadline to determine whether thedeadline threshold has been reached (350).

The estimate of how long it should take the service provider to reachthe destination includes estimates for the time it would take to get tothe destination if the service provider went there directly from thecurrent location plus any time spent providing services to requestingusers along the way. In one aspect, the network computer system 100 canimplement a destination filter mode that offers service providers onlythe service requests that the provider can fulfill along the way to thespecified destination. In an example where the service provider is adriver offering transport services, the time spent providing servicescan account for expected delays that arise through taking a detour topick riders up and drop them off as well as expected wait times forriders to get in and out of the car. This time can be expressed as theexpected_time_to_arrival_with_destination_filter. One example estimatefor that time is:direct_time_to_destination_from_current_location*1.5+20 minutes

The direct_time_to_destination_from_current_location is estimated frommapping resources, such as the mapping engine 135, and the constants areconfigurable. The multiplier accounts for the fact that a longerdistance tends to yield more intermittent service requests. The offsetensures enough buffer time when the destination is nearby. In otheraspects, historical data collected from service providers in thedestination filter mode are used to estimate theexpected_time_to_arrival_with_destination_filter.

As soon as the calculated duration is equal to or greater than the timeleft until the deadline the service provider set, the network computersystem 100 informs the service provider that it is time to head to thedestination through a prompt displayed on the service provider device180 (360). If the service provider is currently providing service to auser when the network computer system 100 determines that it is time tohead towards the destination, the service provider application 185 canwait until the service is completed and then inform the service providerthat he or she should head to the destination.

In response to the prompt to head to the destination, the serviceprovider can choose to enter destination filter mode, set a newdeadline, or remove the deadline entirely (e.g., by providing input).The network computer system 100 can then process the service providerresponse to the prompt (361). If the service provider chooses to enterdestination filter mode, the network computer system 100 sets theservice provider mode and expects the provider to travel towards thedestination. From then on, the network computer system 100 offers theservice provider only service invitations that are on the route from thecurrent location to the destination. Therefore, in destination filtermode, the invites offered to the service provider should not take theservice provider too far away from the route such that he or she cannotmake it to the destination prior to the deadline. In some aspects, theservice provider can configure destination filter mode settings so thatservice invitations can cause the deadline to be exceeded by a fudgefactor (e.g., 5 minutes). Additionally, while in destination filtermode, the service provider can receive preferential treatment (i.e.,boosting) from the network computer system 100 and is considered higherpriority than providers in normal mode for service invitations that arealong the route.

Prior to the deadline threshold being reached, the network computersystem 100 offers the service provider service invitations without anyrestrictions on direction. However, the offered service invitations areconstrained by a deadline filter that checks whether the serviceprovider has time to fulfill the service invitation and still reach thedestination while providing services to requesting users along the way.Therefore, when the network computer system 100 receives a servicerequest from a user (320), the network computer system 100 estimates thetime required for the service provider to travel from the currentlocation to the service start location (322), the service start locationto the service destination (324), and the service destination to thedesired destination. In an example, the user is a prospective passengerthat wants to be picked up at the service start location and dropped offat the service destination.

In order to determine whether a received service request passes thedeadline filter, the network computer system 100 can calculate anexpected time for the service provider to complete the service request.In one example, the expected time at completion is the current time plusan estimate for the time to travel from the current location to theservice start location and then from the service start location to theservice destination, taking into account factors such as trafficconditions and time required at each location to perform aspects of theservice. The deadline filter can additionally estimate how long itshould take the service provider to travel from the service destinationto the desired destination while still accepting and fulfilling servicerequests along the way to the desired destination, expressed as theexpected_time_to_arrival_with_destination_filter. One example estimatefor that time is:direct_time_to_destination_from_service_destination*1.5+20 minutes

As with the deadline threshold, the deadline filter calculation canestimate direct_time_to_destination_from_service_destination frommapping resources, such as the mapping engine 135, and the constants areconfigurable. The multiplier accounts for the fact that a longerdistance tends to yield more intermittent service requests. The offsetensures enough buffer time when the destination is nearby. In otheraspects, historical data collected from service providers in thedestination filter mode are used to estimate theexpected_time_to_arrival_with_destination_filter.

The deadline filter then adds the expected time at the servicedestination and the expected_time_to_arrival_with_destination_filter andcompares the result to the deadline. If the result is on or before thedeadline, the request passes the destination filter and the serviceprovider is a possible candidate for fulfilling the service request(330). If the result is after the deadline, the network computer system100 filters out the service provider from a candidate set of providersand instead chooses a different provider from the candidate set tofulfill the service request (332). In alternative implementations, thenetwork computer system 100 can instead choose an optimal serviceprovider from the candidate set of providers prior to checking whetherthe request passes any filters. In this case, if the chosen optimalservice provider is in deadline filter mode, the network computer system100 then checks whether the request passes the deadline filter, and ifnot, chooses the next available service provider. In another example,when the network computer system receives a service request, the networkcomputer system can identify a set of candidate providers based on theirlocations and the start location of the service request. If the set ofcandidate providers includes a service provider in the deadline filtermode, the network computer system can determine, based on thecomputations described, whether that service provider should be includedin the set of candidate providers. If that service provider is includedin the set, the network computer system can perform a default selectionprocess to select a service provider from this set or select thatservice provider (e.g., given a boost), depending on implementation.

If the service provider is chosen to fulfill the service request, thenetwork computer system 100 sends a service invitation to the provider,who may accept or reject it. Whether the service provider accepts andperforms the service or rejects the invite, the network computer system100 processes the service provider selection and any results (334). Whenthe service provider is available to receive a new service invitation,the network computer system 100 can resume monitoring whether thedeadline threshold has been reached (350).

In some aspects, the network computer system 100 can continue monitoringthe deadline threshold while the service provider is fulfilling aservice request. If the service provider is currently providing serviceto a user when the network computer system 100 determines that it istime to head towards the destination, the service provider application185 can wait until the service is completed and then inform the serviceprovider that he or she should head to the destination. Since therequest for the current service being performed passed the deadlinefilter, this can happen only in situations where traffic conditions onthe route worsen significantly or other aspects of the service requesttake significantly longer than estimated.

FIG. 4 is a flow chart describing an example method of persistingdestination and deadline settings when a service provider goes offline,according to examples described herein. The network computer system 100can receive a destination and a deadline from a service provider thatspecify what time the service provider would like to stop providingservice and where that service provider would like to be at that time(410). For example, a driver could select that he or she wants to be ata restaurant at 7 p.m. In this example, the destination is therestaurant specified by the service provider and the deadline is 7 p.m.

A provider management interface 115 of the network computer system 100can process the destination and deadline request and update the modeassigned to the service provider to reflect the received destination anddeadline. In some aspects, the provider management interface 115 canverify the destination and any constraints on the minimum and maximumacceptable deadlines to confirm the validity of the request. Theprovider management interface 115 can also determine whether the serviceprovider meets any necessary conditions to activate the deadline filtermode. For example, features of the deadline filter mode, such as theability to specify a destination, may be limited in frequency of use.Once verified, the provider management interface 115 can place theservice provider in the deadline filter mode (412). In this mode, thenetwork computer system 100 attempts to ensure that the service providerdoes not receive service invitations that would take the provider toofar away from the destination such that he or she would be unable toreach the desired destination by the deadline.

In some aspects, a service provider can switch to an offline mode inwhich he or she is not available for receiving service invitations(420). For example, the service provider may go offline at the end of aplanned shift or the end of the day. In other examples, the serviceprovider takes a short break with the intention to resume acceptingservice invitations after the break. When a service provider in deadlinefilter mode goes offline, the network computer system 100 can retain thedestination and deadline settings so that the service provider canresume operating in deadline filter mode when he or she comes backonline.

In one implementation, the service provider application 185 or anotherbackground process on the service provider device 180 can continuallymonitor whether the deadline passes or expires while the serviceprovider is offline (430). If the deadline passes, the service providerapplication 185 can remove the destination and deadline settings andupdate the network computer system 100 accordingly. In an alternateimplementation, the network computer system 100 can continue to monitorthe deadline even when the service provider is offline. If the deadlinepasses, the network computer system 100 can remove the destination anddeadline settings from the provider data 190 (435).

Once the service provider chooses to resume receiving service requeststhrough the service provider application 185, the network computersystem 100 receives an indication that the provider is back online(440). In order to ensure that the service provider can reach thedesired destination by the deadline, the network computer system 100checks the current location of the service provider and estimates howlong it should take the service provider to reach the destination whileproviding services to requesting users along the way. The networkcomputer system 100 adds the estimate to the current time and comparesthat to the deadline to determine whether the deadline threshold hasbeen reached (450).

The estimate of how long it should take the service provider to reachthe destination includes estimates for the time it would take to get tothe destination if the service provider went there directly from thecurrent location plus any time spent providing services to requestingusers along the way. In one aspect, the network computer system 100 canimplement a destination filter mode that offers service providers onlythe service requests that the provider can fulfill along the way to thespecified destination. In an example where the service provider is adriver, the time spent providing services can account for expecteddelays that arise through taking a detour to pick riders up and dropthem off as well as expected wait times for riders to get in and out ofthe car. This time can be expressed as theexpected_time_to_arrival_with_destination_filter. One example estimatefor that time is:direct_time_to_destination_from_current_location*1.5+20 minutes

The direct_time_to_destination_from_current_location is estimated frommapping resources, such as the mapping engine 135, and the constants areconfigurable. The multiplier accounts for the fact that a longerdistance tends to yield more intermittent service requests. The offsetensures enough buffer time when the destination is nearby. In otheraspects, historical data collected from service providers in thedestination filter mode are used to estimate theexpected_time_to_arrival_with_destination_filter.

As soon as the calculated duration is equal to or greater than the timeleft until the deadline the service provider set, the network computersystem 100 informs the service provider that it is time to head to thedestination through a prompt displayed on the service provider device180 (460). In some implementations, the network computer system 100 cancontinue to monitor the current location of the service provider anddetermine whether the deadline threshold has been reached even while theprovider is offline. If so, the network computer system 100 can promptthe offline service provider to begin heading towards the destinationand/or come online and change to destination filter mode in order toreach the destination by the deadline.

In one implementation, the prompt generated in response to the deadlinethreshold being reached is a modal window displayed through the serviceprovider application 185. This modal window can give the serviceprovider three options.

In a first option, the service provider can choose to enter destinationfilter mode (462). The network computer system 100 places the providerin destination filter mode and begins filtering service invitations toonly those that are on the route between the service provider's currentlocation and the set destination (470). Upon choosing this option, theservice provider application 185 can also display information related tothe destination filter mode such as special conditions that may apply inthat mode.

In a second option, the service provider can choose to delay enteringdestination filter mode and remain in deadline filter mode for longer bysetting a new, later deadline (464).

In a third option, the service provider can choose to cancel thedeadline and remove the destination (466). With this option, theprovider is no longer in deadline filter mode and does not enterdestination filter mode. Instead, the network computer system 100 placesthe service provider in regular mode indicating a normal online status(475).

FIG. 5 is a flow chart describing an example method of filtering servicerequests by destination, according to examples described herein. In oneaspect, the network computer system 100 can receive a destination from aservice provider that specifies where the provider is traveling (510).In another aspect, the network computer system 100 has a storeddestination for a service provider who is in deadline filter mode. Oncethe deadline threshold for the deadline filter mode is reached, thenetwork computer system 100 can transition the service provider intodestination filter mode. For example, a driver can set a home address asthe destination when the driver is headed home.

A provider management interface 115 of the network computer system 100can process the destination request and update the mode assigned to theservice provider to reflect the destination. In some aspects, theprovider management interface 115 can verify the destination and anyconstraints on the destination to confirm the validity of the request.The provider management interface 115 can also determine whether theservice provider meets any necessary conditions to activate thedestination filter mode. For example, features of the destination filtermode may be limited in frequency of use. Once verified, the providermanagement interface 115 can place the service provider in thedestination filter mode (512).

Prior to reaching the destination, the network computer system 100filters out service requests so that the provider is only offeredservice invitations that are along the route from the provider's currentlocation to the destination. Therefore, when the network computer system100 receives a service request from a user (520), the network computersystem 100 checks the service start location (522) and servicedestination (524) and determines whether paths from the provider'scurrent location to the service start location and service destinationare near or along the route from the current location to the desireddestination (530). In one example, the user is a prospective passengerthat wants to be picked up at the service start location and dropped offat the service destination. If the service start location and servicedestination are not near or along the provider's route from the currentlocation to the desired destination (e.g., the service start locationand/or service destination are not within a threshold distance from apoint along the route of travel), the network computer system 100filters out the service provider from a candidate pool of providers andinstead chooses a different provider from the candidate pool to fulfillthe service request (532). On the other hand, if the service startlocation and service destination are near or along the provider's routefrom the current location to the desired destination, the serviceprovider is a viable candidate for fulfilling the service request, andthe network computer system 100 can proceed to process service providerselection and results (534).

The network computer system 100 can utilize the current locations of theservice providers in a region in order to choose an optimal serviceprovider to fulfill the service request (535). As provided herein, theoptimal service provider can be a service provider that is closest tothe service requester with respect to distance or time, or can be aproximate service provider that is optimal for other reasons, such asthe service provider's experience, the amount of time the serviceprovider has been on the clock, the service provider's current earnings,and the like. In some implementations, the network computer system 100can prioritize service providers in destination filter mode for servicerequests that are near or along the provider's route from the currentlocation to the desired destination.

Once the optimal service provider is selected, the network computersystem 100 can generate a service invitation to fulfill the servicerequest and transmit the service invitation to the optimal serviceprovider's device via the service provider application 185 (540). Uponreceiving the service invitation, the optimal service provider caneither accept or reject the invitation. Rejection of the invitation cancause the network computer system 100 to select a next available serviceprovider from the candidate set of service providers to fulfill theservice request (542). However, if the optimal service provider accepts(e.g., via an acceptance input on a user interface of the serviceprovider application 185), then the acceptance input can be transmittedback to the network computer system 100, which can generate and transmitinformation identifying the optimal service provider to the servicerequester via the service requester application 175 on the servicerequester device 170 (544). The service provider then fulfills theservice request at the service start location and/or service destination(545). In an example using transport services, the service providerpicks up the service requester at the service start location and dropsoff the service requester at the service destination.

When the service provider is available to receive a new serviceinvitation (either through rejecting an invitation or completingservice), the network computer system 100 or the service provider device180 itself can resume monitoring and checking the service providerlocation to determine if the provider has arrived at the desireddestination (550). Once the provider has arrived at the desireddestination, the service provider application 185 can place the serviceprovider in an offline mode wherein the provider is not available toreceive service invitations (560). Alternatively, the service providerapplication 185 can prompt the provider to choose whether to go offlineor return to a regular service mode.

User Interface Examples

FIGS. 6A and 6B illustrate example user interfaces on a service providerdevice, according to examples described herein. In one example,execution of the service provider application 185 on the serviceprovider device 180 can cause the device to generate an applicationinterface on the device's touch-sensitive display.

In the example user interface illustrated in FIG. 6A, a service providercan enter deadline filtering mode by choosing a destination and adeadline that specify what time the service provider would like to stopproviding service and where that service provider would like to be atthat time (e.g., by providing input). For example, a driver providingtransport services could select that he or she wants to be home at 7p.m. In this example, the destination is the provider's home address andthe deadline is 7 p.m. Once in deadline filtering mode, the networkcomputer system 100 attempts to ensure that the service provider doesnot receive service invitations that would take the provider too faraway from the destination such that he or she would be unable to reachthe desired destination by the deadline.

In one implementation, when not currently providing service to a user,the service provider can select a menu icon on the service providerapplication 185 to request deadline filtering mode. In response, theservice provider application 185 can display the interface shown in FIG.6A to allow the provider to set a destination and a deadline. Theservice provider can choose the destination from saved locations orsearch for a new address to use as the destination. The nearestselectable deadline, or arrival time, that the service provider isallowed to select is the soonest time such that the network computersystem 100 is confident that it can route the service provider from thecurrent location to the destination in time while the service providerfulfills service requests along the way. In addition, the user interfacecan limit the latest selectable arrival time to a longest reasonablelength of a shift (e.g., 12 hours). Once the service provider selects adestination and a deadline, the provider can press the DONE button totransmit the request to the network computer system 100.

In some aspects, the network computer system 100 can verify thedestination and any constraints on the minimum and maximum acceptabledeadlines to confirm the validity of the request. The network computersystem 100 can also determine whether the service provider meets anynecessary conditions to activate the deadline filter mode. For example,features of the deadline filter mode, such as the ability to specify adestination, may be limited in frequency of use. Once verified, thenetwork computer system 100 can place the service provider in thedeadline filter mode.

FIG. 6B illustrates an example modal window displayed when the deadlinethreshold has been reached. In order to ensure that the service providercan reach the desired destination by the deadline, the network computersystem 100 tracks the current location of the service provider andestimates how long it should take the service provider to reach theselected destination while providing services to requesting users alongthe way. At periodic intervals while the service provider is in deadlinefilter mode, such as every time the current location of the serviceprovider changes or once per minute, the network computer system 100adds the estimate to the current time and compares that to the deadlineto determine whether the deadline threshold has been reached

As soon as the deadline threshold is reached, the network computersystem 100 informs the service provider that it is time to head to thedestination through a prompt displayed on the service provider device180 through the service provider application 185. If the serviceprovider is currently providing service to a user when the networkcomputer system 100 determines that it is time to head towards thedestination, the service provider application 185 can wait until theservice is completed and then inform the service provider that he or sheshould head to the destination.

When presented with the modal window shown in FIG. 6B, the serviceprovider can choose to enter destination filter mode by selecting OK.From then on, the network computer system 100 offers the serviceprovider only service invitations that are on the route from the currentlocation to the destination. Therefore, in destination filter mode, theinvites offered to the service provider should not take the serviceprovider too far away from the route such that he or she cannot make itto the destination prior to the deadline. Alternatively, the serviceprovider can select REMOVE to ignore the deadline and return to a normalonline status mode. In a further alternative not illustrated, theservice provider can choose a new deadline using an interface such asthe one illustrated in FIG. 6A.

In some aspects, the user interface of the service provider application185 can display an indication to the service provider that the provideris in deadline filter mode. This indication can also include theselected deadline. For example, the top portion of the user interfacecan display that the provider is online and that he or she has a “7:00p.m. destination scheduled.” Furthermore, when the service provider isoffline, the user interface can retain the deadline and continue todisplay the deadline in the illustrated status bar. In addition, a mapdisplayed as part of the user interface can indicate the selecteddestination with an icon such as a star at the destination.

Service Provider Device

FIG. 7 is a block diagram illustrating an example service providerdevice executing a designated service provider application for anon-demand service, as described herein. In many implementations, theservice provider device 780 can comprise a mobile computing device, suchas a smartphone, tablet computer, laptop computer, VR or AR headsetdevice, and the like. As such, the service provider device 780 caninclude typical telephony features such as a microphone 745, a camera750, and a communication interface 710 to communicate with externalentities using any number of wireless communication protocols. Incertain aspects, the service provider device 780 can store a designatedapplication (e.g., a service provider application 732) in a local memory730. In many aspects, the service provider device 780 further storesinformation corresponding to a contacts list 734 and calendarappointments 736 in the local memory 730. In variations, the memory 730can store additional applications executable by one or more processors740 of the service provider device 780, enabling access and interactionwith one or more host servers over one or more networks 760.

In response to a user input 718, the service provider application 732can be executed by a processor 740, which can cause an applicationinterface to be generated on a display screen 720 of the serviceprovider device 780. The application interface can enable the serviceprovider to, for example, check current price levels and availabilityfor the on-demand arrangement service. In various implementations, theapplication interface can further enable the service provider to selectfrom multiple ride service types, such as a carpooling service type, aregular ride-sharing service type, a professional ride service type, avan on-demand service type, a luxurious ride service type, and the like.

The provider can enter various states or modes, such as online mode,destination filter mode, and deadline filter mode via user inputs 718provided on the application interface. For example, the provider canselect which types of service he or she is available to provide as wellas a desired destination 714 and deadline 716 to be at that destination.As provided herein, the service provider application 732 can furtherenable a communication link with a network computer system 700 over thenetwork 760, such as the network computer system 100 as shown anddescribed with respect to FIG. 1. Furthermore, as discussed herein, theservice provider application 732 can display requester information 742on the application interface that includes data regarding a servicerequester so that the provider can choose whether to accept or reject aservice invitation received from the network computer system 700.

The processor 740 can transmit the provider status 713 (i.e., modes theprovider is in) via a communications interface 710 to the backendnetwork computer system 700 over a network 760. In various examples, theservice provider device 780 can further include a GPS module 755, whichcan provide location data 762 indicating the current location of theprovider to the network computer system 700 to, for example, select anoptimal service provider or filter the provider based on destination 714and deadline 716. In alternative aspects, hard-wired circuitry may beused in place of or in combination with software instructions toimplement aspects described herein. Thus, aspects described are notlimited to any specific combination of hardware circuitry and software.

Hardware Diagram

FIG. 8 is a block diagram that illustrates a computer system upon whichexamples described herein may be implemented. A computer system 800 canbe implemented on, for example, a server or combination of servers. Forexample, the computer system 800 may be implemented as part of a networkservice for providing service services. In the context of FIG. 1, thenetwork computer system 800 may be implemented using a computer system800 such as described by FIG. 8. The network computer system 100 mayalso be implemented using a combination of multiple computer systems asdescribed in connection with FIG. 8.

In one implementation, the computer system 800 includes processingresources 810, a main memory 820, a read-only memory (ROM) 830, astorage device 840, and a communication interface 850. The computersystem 800 includes at least one processor 810 for processinginformation stored in the main memory 820, such as provided by a randomaccess memory (RAM) or other dynamic storage device, for storinginformation and instructions which are executable by the processor 810.The main memory 820 also may be used for storing temporary variables orother intermediate information during execution of instructions to beexecuted by the processor 810. The computer system 800 may also includethe ROM 830 or other static storage device for storing staticinformation and instructions for the processor 810. A storage device840, such as a magnetic disk or optical disk, is provided for storinginformation and instructions.

The communication interface 850 enables the computer system 800 tocommunicate with one or more networks 880 (e.g., cellular network)through use of the network link (wireless or wired). Using the networklink, the computer system 800 can communicate with one or more computingdevices, one or more servers, and/or one or more self-driving vehicles.In accordance with examples, the computer system 800 receives servicerequests 882 from mobile computing devices of individual users. Theexecutable instructions stored in the memory 830 can destinationfiltering instructions 824 and deadline filtering instructions 826,which the processor 810 executes to determine whether to filter aservice provider based on destination and/or deadline. In doing so, thecomputer system can receive a provider status 884 for service providersoperating throughout the given region, and the processor can select anoptimal service provider from a set of available service providers andtransmit a service invitation 852 to enable the service provider toaccept or decline the service offer.

By way of example, the instructions and data stored in the memory 820can be executed by the processor 810 to implement an example networkcomputer system 100 of FIG. 1. In performing the operations, theprocessor 810 can receive service requests 882 and provider status 884and submit service invitations 852 to facilitate fulfilling the servicerequests 882.

The processor 810 is configured with software and/or other logic toperform one or more processes, steps and other functions described withimplementations, such as described by FIGS. 1 through 6, and elsewherein the present application.

Examples described herein are related to the use of the computer system800 for implementing the techniques described herein. According to oneexample, those techniques are performed by the computer system 800 inresponse to the processor 810 executing one or more sequences of one ormore instructions contained in the main memory 820. Such instructionsmay be read into the main memory 820 from another machine-readablemedium, such as the storage device 840. Execution of the sequences ofinstructions contained in the main memory 820 causes the processor 810to perform the process steps described herein. In alternativeimplementations, hard-wired circuitry may be used in place of or incombination with software instructions to implement examples describedherein. Thus, the examples described are not limited to any specificcombination of hardware circuitry and software.

It is contemplated for examples described herein to extend to individualelements and concepts described herein, independently of other concepts,ideas or systems, as well as for examples to include combinations ofelements recited anywhere in this application. Although examples aredescribed in detail herein with reference to the accompanying drawings,it is to be understood that the concepts are not limited to thoseprecise examples. As such, many modifications and variations will beapparent to practitioners skilled in this art. Accordingly, it isintended that the scope of the concepts be defined by the followingclaims and their equivalents. Furthermore, it is contemplated that aparticular feature described either individually or as part of anexample can be combined with other individually described features, orparts of other examples, even if the other features and examples make nomentioned of the particular feature. Thus, the absence of describingcombinations should not preclude claiming rights to such combinations.

What is claimed is:
 1. A method for filtering requests for a service,the method being performed by one or more processors of a computingsystem and comprising: receiving, over a network, provider datacorresponding to a specified destination and a deadline from a serviceprovider; tracking a current location of the service provider through adevice equipped with a location-based resource; receiving, over thenetwork, request data corresponding to a plurality of requests forservice from a plurality of user devices; querying one or more mappingresources to determine travel time on a route from the current locationto the specified destination for the service provider; and upondetermining that the travel time added to a current time is within aprogrammed threshold of the deadline, transmitting, to the device, anotification to the service provider to change operation of a serviceapplication running on the device from a first mode to a second mode,wherein when the service application operates in the second mode, thecomputing system: receives, over the network, the current location ofthe service provider from the device; and based on the current locationof the service provider, filters out requests for service which have aservice start location and a service destination that are not within athreshold distance from a point on the route between the currentlocation and the specified destination.
 2. The method of claim 1,wherein the travel time is based at least on a distance between thecurrent location and the specified destination, traffic conditions, andtime to perform aspects of the service.
 3. The method of claim 1,further comprising: in response to receiving the provider datacorresponding to the specified destination and the deadline, changingoperation of the service application running on the device to the firstmode, wherein when the service application operates in the first mode,the computing system filters out any of the plurality of requests forservice in which the service provider is determined unable to provideservice and travel to the specified destination before the deadline,wherein the request data includes the service start location and theservice destination for each of the requests for service, and wherein arequest is identified as being assignable to the service provider whenthe service provider is determined to be able to travel along a routefrom (1) the current location to the service start location of thatrequest, (2) the service start location of that request to the servicedestination of that request, and (3) the service destination of thatrequest to the specified destination, before the deadline.
 4. The methodof claim 1, wherein the notification to the service provider to changeoperation of the service application running on the device from thefirst mode to the second mode triggers a prompt within the serviceapplication, wherein the prompt enables the service provider to selectthe second mode.
 5. The method of claim 4, wherein the prompt furtherenables the service provider to delay entering the second mode for aperiod of time.
 6. The method of claim 1, further comprising: changingoperation of the service application running on the device from thefirst mode to an offline mode when the service provider reaches thespecified destination.
 7. The method of claim 1, wherein thelocation-based resource includes a global positioning system (GPS)receiver.
 8. A network computer system comprising: one or moreprocessors; and one or more memory resources storing instructions that,when executed by the one or more processors, cause the one or moreprocessors to: receive, over a network, provider data corresponding to aspecified destination and a deadline from a service provider; track acurrent location of the service provider through a device equipped witha location-based resource; receive, over the network, request datacorresponding to a plurality of requests for service from a plurality ofuser devices; query one or more mapping resources to determine traveltime on a route from the current location to the specified destinationfor the service provider; and upon determining that the travel timeadded to a current time is within a programmed threshold of thedeadline, transmit, to the device, a notification to the serviceprovider to change operation of a service application running on thedevice from a first mode to a second mode, wherein when the serviceapplication operates in the second mode, the network computer system:receives, over the network, the current location of the service providerfrom the device; and based on the current location of the serviceprovider, filters out requests for service which have a service startlocation and a service destination that are not within a thresholddistance from a point on the route between the current location and thespecified destination.
 9. The network computer system of claim 8,wherein the travel time is based at least on a distance between thecurrent location and the specified destination, traffic conditions, andtime to perform aspects of a service associated with the networkcomputer system.
 10. The network computer system of claim 8, furthercomprising instructions for: in response to receiving the provider datacorresponding to the specified destination and the deadline, changingoperation of the service application running on the device to the firstmode, wherein when the service application operates in the first mode,the network computer system filters out any of the plurality of requestsfor service in which the service provider is determined unable toprovide service and travel to the specified destination before thedeadline, wherein the request data includes the service start locationand the service destination for each of the requests for service, andwherein a request is identified as being assignable to the serviceprovider when the service provider is determined to be able to travelalong a route from (1) the current location to the service startlocation of that request, (2) the service start location of that requestto the service destination of that request, and (3) the servicedestination of that request to the specified destination, before thedeadline.
 11. The network computer system of claim 8, wherein thenotification to the service provider to change operation of the serviceapplication running on the device from the first mode to the second modetriggers a prompt within the service application, wherein the promptenables the service provider to select the second mode.
 12. The networkcomputer system of claim 11, wherein the prompt further enables theservice provider to delay entering the second mode for a period of time.13. The network computer system of claim 8, further comprisinginstructions for: changing operation of the service application runningon the device from the first mode to an offline mode when the serviceprovider reaches the specified destination.
 14. The network computersystem of claim 8, wherein the location-based resource includes a globalpositioning system (GPS) receiver.
 15. A non-transitory computerreadable medium storing instructions that, when executed by one or moreprocessors of a network computer system, cause the one or moreprocessors to: receive, over a network, provider data corresponding to aspecified destination and a deadline from a service provider; track acurrent location of the service provider through a device equipped witha location-based resource; receive, over the network, request datacorresponding to a plurality of requests for service from a plurality ofuser devices; query one or more mapping resources to determine traveltime on a route from the current location to the specified destinationfor the service provider; and upon determining that the travel timeadded to a current time is within a programmed threshold of thedeadline, transmit, to the device, a notification to the serviceprovider to change operation of a service application running on thedevice from a first mode to a second mode, wherein when the serviceapplication operates in the second mode, the network computer system:receives, over the network, the current location of the service providerfrom the device; and based on the current location of the serviceprovider, filters out requests for service which have a service startlocation and a service destination that are not within a thresholddistance from a point on the route between the current location and thespecified destination.
 16. The non-transitory computer readable mediumof claim 15, wherein the request data includes a service start locationand a service destination for each of the requests for service, andwherein a request is identified as being assignable to the serviceprovider when the service provider is determined to travel along on aroute from (1) the current location to the service start location ofthat request, (2) the service start location of that request to theservice destination of that request, and (3) the service destination ofthat request to the specified destination, before the deadline.
 17. Thenon-transitory computer readable medium of claim 15, further comprisinginstructions for: in response to receiving the provider datacorresponding to the specified destination and the deadline, changingoperation of the service application running on the device to the firstmode, wherein when the service application operates in the first mode,the network computer system filters out any of the plurality of requestsfor service in which the service provider is determined unable toprovide service and travel to the specified destination before thedeadline, wherein the request data includes the service start locationand the service destination for each of the requests for service, andwherein a request is identified as being assignable to the serviceprovider when the service provider is determined to be able to travelalong a route from (1) the current location to the service startlocation of that request, (2) the service start location of that requestto the service destination of that request, and (3) the servicedestination of that request to the specified destination, before thedeadline.
 18. The non-transitory computer readable medium of claim 15,wherein the notification to the service provider to change operation ofthe service application running on the device from the first mode to thesecond mode triggers a prompt within the service application, whereinthe prompt enables the service provider to select the second mode. 19.The non-transitory computer readable medium of claim 18, wherein theprompt further enables the service provider to delay entering the secondmode for a period of time.
 20. The non-transitory computer readablemedium of claim 15, further comprising instructions for: changingoperation of the service application running on the device from thefirst mode to an offline mode when the service provider reaches thespecified destination.